Difference between revisions of "User:Mathfantasia"

(Contributions On This Page Only:)
(Contributions On This Page Only:)
 
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6% compounded yearly for 4 years with principal 20000.  We see that 6% interest will make the principal double every 12 years (by the law of 72).  But we only need 4 years, so with no more estimation we would need to know <math>2^{1/3}</math>.  We estimate this with the above linear equations.  So we want to multiply the principal, 20000, by (<math>1 + .8/3</math>).  We end up getting 25336.  And there ya go!  Actual answer: 25250 (less than 1% off ... actually .3%)
 
6% compounded yearly for 4 years with principal 20000.  We see that 6% interest will make the principal double every 12 years (by the law of 72).  But we only need 4 years, so with no more estimation we would need to know <math>2^{1/3}</math>.  We estimate this with the above linear equations.  So we want to multiply the principal, 20000, by (<math>1 + .8/3</math>).  We end up getting 25336.  And there ya go!  Actual answer: 25250 (less than 1% off ... actually .3%)
  
LOL needed a place to latex on the go.  Putting up some calculus notes.
+
Starting a [[K-12 Proofs and Comments]] page.
 
 
We wish to find <math>\int^2_1 x^2dx</math>.  Recall that the formula for integration is <math>\int^b_a f(x)dx = \sum_{i=1}^n (height)(width) = \sum_{i=1}^n f(x_i)((b-a)/2)</math>.  So <math>x_i = a + \frac{(b-a)i}{n} = 1 + \frac{i}{n}</math>.  Width = <math> \frac{(b-a)i}{n} = \frac{i}{n}</math>.  <math>f(x_i) = (1 + \frac{i}{n})^2 = 1 + \frac{2i}{n} +
 
\frac{i^2}{n^2}</math> . The integral = <math>(\sum_{i=1}^n (1 + \frac{i}{n})^2)\frac{1}{n} = (1 + \frac{2i}{n} + \frac{i^2}{n^2})\frac{1}{n} = \frac{1}{n} + \frac{2i}{n^2} + \frac{i^2}{n^3}) = \frac{1}{n}\sum_{i=1}^n 1 + \frac{2}{n^2}\sum_{i=1}^n + i \frac{1}{n^3}\sum_{i=1}^n i^2  </math>
 

Latest revision as of 01:47, 10 May 2016

My Contributions:

Divisibility rules: for 7

Rule 3: "Tail-End divisibility." Note. This only tells you if it is divisible and NOT the remainder. Take a number say 12345. Look at the last digit and add or subtract a multiple of 7 to make it zero. In this case we get 12370 or 12310. Lop off the ending 0's and repeat. 1237 ==> 123 ==> 130 ==> 13 NOPE. Works in general with numbers that are relatively prime to the base (and works GREAT in binary).


Contributions On This Page Only:

Estimating Compound Interest

Look up and understand the "Rule of 72." My short synopsis here says that certain small percentages, say n%, will double in "72 divided by n" years.

I will now estimate $2^x$ between x=0 and x=1 by forming segments between the previous x values and x=.5. So for x<.5 we use 1 + .8x and otherwise 1.2x + .8.

I will now give an example of this method!

6% compounded yearly for 4 years with principal 20000. We see that 6% interest will make the principal double every 12 years (by the law of 72). But we only need 4 years, so with no more estimation we would need to know $2^{1/3}$. We estimate this with the above linear equations. So we want to multiply the principal, 20000, by ($1 + .8/3$). We end up getting 25336. And there ya go! Actual answer: 25250 (less than 1% off ... actually .3%)

Starting a K-12 Proofs and Comments page.